WO2022265444A1 - Mounting apparatus for antenna device on rooftop conner - Google Patents

Abstract

The present invention relates to a mounting apparatus for an antenna device on a rooftop corner. In particular, the mounting apparatus is installed on a railing on a corner side of a rooftop, and comprises: a floor support part which is disposed on the inner bottom surface of the railing of the roof top and has a part that extends upward in parallel to the railing; a pair of railing support parts extending horizontally from the upper portion of the floor support part toward the railing; and a mounting part which is coupled to the upper portion of the floor support part and has a top end on which an antenna device is mounted. Therefore, the present invention provides installation convenience and enables legal regulations to be met.

Description

Installation device of antenna device for rooftop corner

The present invention relates to a MOUNTING APPARATUS FOR ANTENNA DEVICE ON ROOFTOP CONNER, and more specifically, to meet installation height regulations, but can be easily installed without physically changing the exterior of the building. , It relates to an installation device for an antenna device for a rooftop corner that can be hidden and installed so as not to be exposed to the outside of an optical cable, is easy to adjust the direction of the antenna device, and does not require many workers.

Antennas for wireless communication are generally installed in high places with open surroundings for smooth transmission and reception with devices for wireless communication located at a long distance.

To this end, antennas are installed on utility poles, steel towers, and building rooftops (rooftops), and are often installed on building rooftops in urban areas.

In this case, in order to install the antenna on the roof of the building, a method in which a separate pole for supporting the antenna in an upright state is installed on the roof of the building, and the antenna is fixed and installed on the pole is mainly used.

At this time, the pole is often fixedly installed using an anchor or the like on the floor of the roof of the building. However, in this case, a hole must be drilled in the roof floor of the building to fix the pole, which inevitably entails damage to the building. In addition, when installed on the roof (rooftop) of a building, there is also a problem in that installation costs greatly increase as the weight of installation materials including poles is considerable and large transport machines such as cranes are required.

In addition, when the antenna device is installed on the roof of a building, there is a problem in that it must satisfy various laws and regulations of the country in which it is installed. For example, in countries such as the United States, in order to install an antenna device on the roof of a building, the diagonal length of the antenna device is required not to exceed 3 ft to prevent accidents caused by collapse of installation materials due to strong wind pressure. On the other hand, There are various regulations and safety standards for the operation of heavy equipment such as large cranes.

The present invention has been made to solve the above technical problems, and the antenna device for rooftop corners can be easily installed on the corner railing of the rooftop without changing the exterior of the building while meeting the installation height regulations of the country in which it is installed. Its purpose is to provide an installation device for

In addition, the present invention is another object of the present invention to provide an installation device for an antenna device for a rooftop corner, which is easy to install on the upper end of a holding pole and can prevent a deterioration in appearance by hiding a cable. .

In addition, another object of the present invention is to provide an installation device for an antenna device for a rooftop corner in which directivity control of the antenna device is easy.

The object of the present invention is not limited to the tasks mentioned above, and other tasks not mentioned will be clearly understood by those skilled in the art from the following description.

An antenna device installation device for a rooftop corner according to an embodiment of the present invention is installed on the railing on the corner side of the roof top, is disposed on the inner bottom surface of the railing of the roof top, and a part extends upward parallel to the handrail. A floor support portion, a pair of handrail support portions extending horizontally from the top of the floor support portion toward the handrail, and a mounting portion coupled to the top of the floor support portion and having an antenna device mounted thereon.

Here, the floor support unit includes a plurality of weight blocks, a floor support panel installed on the bottom surface of the roof top so that the plurality of weight blocks are mounted, an rim frame forming an edge end of the floor support panel, and the rim Diagonal connection frames arranged to cross each other so as to connect the diagonals of the frames, a lower support portion including a vertical support beam extending a predetermined height in a vertical direction parallel to the handrail at the intersection of the diagonal connection frames and a lower end of the frame frame. An upper support portion including at least two or more inclined support beams connected to each intermediate portion and extending obliquely from the lower end to the intermediate portion of the vertical support beam.

In addition, the upper support portion and the lower support portion may be coupled to each other by any one of a welding coupling method and a bolting coupling method, respectively.

In addition, each of the plurality of weight blocks may be made of a metal material weighing 3 kg or less, and may be individually seated on the upper surface of the floor support panel between the frame frame and the diagonally connected frame.

In addition, any one of the vertical support beam and the at least two or more inclined support beams is provided with an internal space in communication with each other, and a wire installation hole into which an external wire is inserted is formed at the lower end of any one of the at least two or more inclined support beams. It can be.

In addition, the pair of handrail support parts horizontally extend toward the upper end of the handrail adjacent to each other in the middle of the vertical support beam, and include at least two horizontal support beams extending from the upper end of the inclined support beam. can

The pair of handrail support parts may further include a seating panel part coupled to surround an upper end of the handrail and a vibration reducing part supported on an inner wall of the handrail.

In addition, the at least two or more horizontal support beams may be seated and coupled to the seating panel portion such that a front end portion supports the seating panel portion in a gravitational direction.

In addition, the seating panel portion is bent and extended from the top seating panel seated on the upper end of the handrail, the handrail adhesion panel that is bent and extended from the top seating panel and in close contact with the outer wall of the handrail, and the top seating panel, It may include a handrail spaced panel disposed in parallel with respect to the inner wall and spaced apart from each other by a predetermined distance.

In addition, the seating panel unit may further include a horizontal beam mounting rib integrally formed with the upper seating panel and seated so as to surround a portion of the front end of the horizontal support beam.

In addition, the vibration reduction unit is provided at the front end of the clamping bolt and the clamping bolt assembled to the clamping bolt, and the clamping bolt fastened horizontally through the handrail spaced panel spaced apart from the inner wall of the handrail, the An elastic part elastically supported on the inner wall of the handrail may be included.

In addition, the elastic part may be screwed into a spring fastening hole provided at the front end of the clamping bolt, and may be provided as a dish-shaped spring whose diameter gradually increases from the center of the front end of the clamping bolt toward the handrail.

In addition, the mounting unit includes a tilting means for tilting and rotating the upper end of the antenna device coupled to the upper end of the vertical support beam in the forward and backward directions with respect to the lower end, and both left and right ends of the antenna device coupled to the upper end of the vertical support beam It may include a steering means for steering and rotating in the left and right directions.

In addition, the steering means mediates the coupling of the antenna device to the vertical support beam, and a steering mounting panel that is tilted in conjunction with the tilting rotation of the antenna device in the front and rear directions by the tilting means, and the steering mounting panel A pair of left and right steering guide slots formed through a predetermined steering rotation trajectory in the vertical direction and a pair of left and right steering guide bolts that pass through the lower part of the pair of left and right steering guide slots and are fastened to the lower surface of the antenna device can include

In addition, the steering mounting panel may be coupled to an upper end of the vertical support beam via the tilting means.

In addition, the tilting means is integrally formed on the lower surface of the steering mounting panel provided to mediate the coupling of the antenna device to the vertical support beam, and a part of the hinge to form a left and right tilting axis inside the vertical support beam A fixed tilting panel, a pair of tilting guide panels integrally formed on the lower surface of the steering mounting panel to be parallel to the tilting panel on both left and right sides of the tilting panel, and connected to a lower end of the tilting panel, the tilting panel It may include a tilting adjustment bolt for tilting and adjusting the predetermined angle in the front and rear directions.

In addition, a worm wheel gear tooth is formed on the outer circumferential surface of the lower end of the tilting panel, a worm gear tooth meshed with the worm wheel gear tooth is formed on a part of the outer circumferential surface of the tilting adjustment bolt, and the tilting adjustment bolt is front and back inside the upper end of the vertical support beam. It can be combined horizontally in the direction.

In addition, the tilting adjustment bolt is provided with a tilting adjustment unit exposed to the outside through the vertical support beam corresponding to the inward direction of the handrail, and the antenna device according to the amount of rotation of the tilting adjustment bolt through the tilting adjustment unit. The tilting angle of can be adjusted.

In addition, the tilting means is integrally formed on the upper surface of the vertical support beam, and a tilting slot through which the lower end of the tilting panel passes and a pair of tilting guide slots through which the lower end of the pair of tilting guide panels passes The formed tilting mounting panel may be further included.

In addition, a control box is further installed in the middle of the vertical support beam, and an optical cable connecting the control box and the antenna device vertically penetrates the steering mounting panel, but is provided by a concealed cover installed on the rear surface of the antenna device. It can be installed hidden from the outside.

According to the installation device of the antenna device for the rooftop corner according to an embodiment of the present invention, it is possible to easily install the antenna device on the railing on the corner side of the rooftop without changing the exterior of the building while meeting the installation height regulations of the country in which it is installed. have an effect

In addition, according to the present invention, since the optical cable can be installed without external exposure, it has an effect of improving the external beauty.

In addition, the present invention has an effect of facilitating manual adjustment in directivity adjustment of the antenna device.

1A to 1C are perspective views showing the installation of various numbers of antenna devices using an installation device for antenna devices for rooftop corners according to an embodiment of the present invention,

2 is a perspective view showing an installation process of an antenna device using a floor support portion and a mounting portion among configurations of an installation device for an antenna device for a rooftop corner according to an embodiment of the present invention;

3A and 3B are a downward perspective view and an upward perspective view showing a state in which a single antenna device is installed at a corner of a rooftop,

4 and 5 are exploded perspective views and cross-sectional views showing the vibration reduction unit of the configuration of the installation device of the antenna device for the rooftop corner according to an embodiment of the present invention,

6 is a partially exploded perspective view and a partially enlarged view showing a steering means of an antenna device;

7 and 8 are partially exploded perspective views, partially enlarged views, and cut-away perspective views illustrating the tilting means of the antenna device.

<Description of codes>

1: handrail 2: floor surface

5: border frame 6: floor support panel

7: diagonal connection frame 10: bottom support

11: weight block 13: vertical support beam

14: inclined support beam 15: horizontal support beam

15,21,27: Handrail support part 21: Seating panel part

22: top mounting panel 22A: horizontal beam mounting rib

23A: handrail close panel 23B: handrail spaced panel

27: vibration reduction unit 28: clamping bolt

29: clamping nut 30: elastic part

40: tilting means 41: tilting panel

42: worm wheel gear 43: tilting guide panel

44: tilting mounting panel 44A: tilting slot

44B: tilting guide slot 45: tilting adjustment bolt

46: worm gear 47A: hinge installation part

49: tilting shaft hole 50: steering means

51: steering mounting panel 52: steering guide slot

53: steering guide bolt

Hereinafter, an installation apparatus for an antenna device for a rooftop corner according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

In adding reference numerals to components of each drawing, it should be noted that the same components have the same numerals as much as possible even if they are displayed on different drawings. In addition, in describing an embodiment of the present invention, if it is determined that a detailed description of a related known configuration or function hinders understanding of the embodiment of the present invention, the detailed description will be omitted.

In describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are only used to distinguish the component from other components, and the nature, sequence, or order of the corresponding component is not limited by the term. In addition, unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by a person of ordinary skill in the art to which the present invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and unless explicitly defined in this application, they should not be interpreted in an ideal or excessively formal meaning. don't

1A to 1C are perspective views showing the installation of various numbers of antenna devices using the installation device for rooftop corner antenna devices according to an embodiment of the present invention, and FIG. 2 is a rooftop according to an embodiment of the present invention. It is a perspective view showing the installation process of the antenna device using the floor support part and the mounting part among the configuration of the installation device of the corner antenna device, and FIGS. and an upward perspective view.

As shown in FIGS. 1 to 3B, the installation device of the roof top corner antenna device according to an embodiment of the present invention is installed on the corner side railing 1 of the roof top, A floor support portion 10 disposed on the inner floor surface 2 adjacent to the handrail and partially extending upward in parallel to the handrail 1, and a handrail adjacent to each other at the top of the floor support portion 10, respectively. (1) a pair of handrail support portions 15, 21, 27 horizontally extending toward one of the upper portions of the floor support portion 10, and a mounting portion on which the antenna device A is mounted on top ( 40,50).

Here, as for the antenna device A, as referenced in FIG. 1A, a single number of antenna devices A may be coupled to the top of a vertical support beam 13 provided in a singular number, which will be described later, and referred to in FIG. 1B. As such, the two antenna devices A1 and A2 may be coupled via the antenna mounting beam 16 coupled to the top of the vertical support beam 13 but branched into two, as shown in FIG. 1c, Three antenna devices (A1, A2, A3) may be combined through the antenna mounting beam 17, which is coupled to the top of the vertical support beam 13 and branched into three.

As shown in FIG. 1A, when a single number of antenna devices (A) are coupled to the top of the vertical support beam 13, the antenna device (A) is advantageously beam-forming in the direction outside the building. It is preferable that the front is installed toward the corner of the corner side of the handrail (1) of the rooftop.

In addition, as shown in FIG. 1B, when two antenna devices A are coupled to the antenna mounting beam 16 branched into two, the front surfaces of the antenna devices A1 and A2 can be installed in the same direction ( a), the front surfaces of the antenna devices (A1 and A2) are installed in opposite directions, but one (A1) faces the corner of the corner side of the handrail (1) of the rooftop, and the other (A2) is the rooftop It can be installed facing the inside of (b), but installed so that the fronts of the antenna devices (A1, A2) face different directions, but can be installed facing a direction at an angle of 45 degrees with respect to the handrail (1) (c ), but installed so that the front surfaces of the antenna devices A1 and A2 face different directions, and may be installed so as to face a direction orthogonal to the handrail 1 (d).

And, as referenced in FIG. 1c, when three antenna devices (A1, A2, A3) are coupled to the antenna mounting beam 17 branched into three, each antenna device (A) beams 120 degrees out of omnidirectional. Since the three antenna devices (A1, A2, and A3) can cover the front angle in the forming angle range, the front of each antenna device (A1, A2, and A3) faces the railing (1) of the rooftop corner in the appropriate direction. It has the advantage that it can be deployed to

In addition, as shown in FIGS. 3A and 3B , the floor support unit 10 has almost all components except for the upper end of the vertical support beam 13 and the antenna device A installed thereon at the top of the handrail 1. As it is installed at a position lower than or approximately the same height (in the case of the handrail support parts 15, 21, and 27), simple installation within the range of not deteriorating the aesthetics of the building exterior when observed from the outer lower portion of the handrail 1 also has possible advantages.

On the other hand, as shown in FIG. 2, the floor support unit 10 is seated and disposed on a plurality of weight blocks 11 and the inner floor surface 2 adjacent to the corner railing 1 of the roof top. It may include lower support parts 5 , 6 and 7 and upper support parts 13 and 14 disposed above the lower support parts 5 , 6 and 7 .

Here, the plurality of weight blocks 11, for example, when the weight of the antenna device (A) is 30 kg, the antenna device (A) does not move and is firmly attached to the inner bottom surface (2) of the rooftop by more than 10 times. Ten or more blocks each weighing 30 kg may be provided to support the load. However, it is not necessarily limited to this, and it is also possible to be provided with more or less numbers in consideration of the installation environment such as air volume and wind speed of the roof top to be installed.

In particular, when the weight of each weight block 11 is 30 kg or less, even if there is only one installation worker, one worker can transport it using the elevator or stairs of the building without using heavy equipment such as a crane, It can save installation cost and manpower.

The installation device of the antenna device for the roof top corner according to an embodiment of the present invention is a plurality of weight blocks 11 as well as a floor support part belonging to other installation materials so that it can be transported sufficiently with only one worker's pure manpower. (10) and handrail supports (15, 21, 27) are designed so that the weight of individual components does not exceed 30 kg.

Furthermore, as shown in FIG. 2 , a plurality of weight body blocks 11 may be arranged in a row so as to form one layer long in a certain direction on top of the floor support panel 6 .

More specifically, as shown in FIG. 2 (b), the plurality of weight body blocks 11 are provided with a metal material weighing 30 kg or less, respectively, of the lower support portions 5, 6, and 7 to be described later. During construction, it may be individually seated on the upper surface of the floor support panel 6 between the frame frame 5 and the diagonal connection frame 7.

In addition, although not shown in the drawings, the plurality of weight body blocks 11 can be formed to enable stable stacking in a form that is manufactured to a certain standard and mutually molded like a block toy of Lego. In this case, the plurality of weight blocks 11 may be provided with handles to enable stable transportation by one installer, and the handles may be formed so as not to interfere when stacking the plurality of weight blocks 11. .

On the other hand, the floor support unit 10 may serve to fix the upper end of the support beam 13 at a height that satisfies the regulated height of the antenna device A. The height of the antenna device A here may be adjustable by changing the installation positions of the mounting parts 40 and 50 for the vertical support beam 13 to be described later.

More specifically, in the lower support portions 5, 6, and 7 of the floor support portion 10, as referred to in (a) to (c) of FIG. 2, a plurality of weight blocks 11 are mounted. The floor support panel 6 installed on the bottom surface 2 of the roof top, the frame frame 5 forming the edge end of the floor support panel 6, and the frame frame 5 are connected diagonally to each other as much as possible. Diagonal connecting frames 7 arranged crosswise may be included.

The floor support panel 6 may be provided in a substantially rectangular (or square) steel plate shape, and the frame frame 5 may be welded to the edge portion of the floor support panel 6 or bolted. It may be provided with a rigid frame material connected by a coupling method, and the diagonal connection frame 7 is diagonally connected to each other of the corners of each corner of the floor support panel 6 of which the rectangle (or square) is a steel plate. It may be provided with a cross-arranged rigid frame material.

Here, although not shown in the drawings, a plurality of levelers may be provided below the bottom support panel 6 or the frame frame 5 to adjust the equilibrium with respect to the bottom surface 2 of the roof top. A plurality of levelers, after installing and assembling the lower support parts (5, 6, 7) on the bottom surface (2) of the roof top, adjusting the balance using the leveler, and then using the handrail support parts (15, 21, 27) It plays a role in helping to stably fix and install to the corner side railing (1) of the roof top.

On the other hand, the upper support parts 13 and 14 of the configuration of the floor support part 10 are vertical in parallel with the handrail 1 at the intersection of the diagonally connected frames 7, as shown in (c) of FIG. At least two or more vertical support beams 13 extending at a predetermined height in the direction, the lower end connected to each intermediate portion of the frame frame 5, and the upper end extending obliquely from the lower end connected to the intermediate portion of the vertical support beam 13 An inclined support beam 14 may be included.

Since the bottom of the inclined support beam 14 is connected to each middle part of the frame frame 5, respectively, the frame frame 5 is provided with four corresponding to the number of each side of the rectangular bottom support panel 6, It is preferable that the number of inclined support beams 14 is also provided with four.

On the other hand, the term 'middle part' used herein does not mean exactly physically the middle of both ends of the indicated configuration, but includes all the remaining parts except for one end and the other end when the indicated configuration is divided into three parts. meaning must be interpreted.

Here, the upper support portions 13 and 14 and the lower support portions 5, 6, and 7 are all provided with a rigid frame material (steel plate material), a method suitable for the coupling method of the rigid frame material (or steel plate material). As one of them, it may be mutually coupled by any one of a welding coupling method and a bolting coupling method.

On the other hand, although not shown in detail in the drawing, any one of the vertical support beam 13 and at least two or more inclined support beams 14 is provided so that the internal space communicates with each other, and among the at least two or more inclined support beams 14 A wire installation hole (not shown) into which an external wire is inserted may be formed at one lower end.

In this way, the external wire is inserted and installed from the floor surface (2) near the handrail (1) of the roof top through the wire installation hole of the inclined support beam (14), respectively, the inclined support beam (14) and the vertical support beam (13). ) through the inner space of the antenna device (A) is installed so as to extend to the side where the antenna device (A) is installed, it is possible to simplify the wiring design of complex external wires, and to prevent the exterior beauty of the building from being deteriorated by the external wires.

On the other hand, as referenced in (d) and (e) of FIG. 2, the pair of handrail support portions 15, 21, and 27 are adjacent to each other in the middle of the vertical support beam 13. It may include at least two or more horizontal support beams 15 extending from the vertical support beam 13 corresponding to the upper end of the inclined support beam 14, each extending horizontally toward the upper end of the ).

The horizontal support beams 15 are preferably provided one by one so that their front ends are seated orthogonally at 90 degrees with respect to two adjacent handrails 1 each having a corner of 90 degrees.

At this time, at least two or more horizontal support beams 15 may be seated and coupled to the seating panel portion 21 such that the front end portion supports the seating panel portion 21 to be described later with a load in the direction of gravity. This will be described in more detail later.

4 and 5 are exploded perspective views and cross-sectional views showing a vibration reduction unit among configurations of an installation device for an antenna device for a rooftop corner according to an embodiment of the present invention.

A pair of handrail support portions 15, 21, and 27, as shown in FIGS. 4 and 5, the mounting panel portion 21 coupled to surround the upper end of the handrail 1 and the handrail 1 A vibration reducing unit 27 supported on the inner wall may be further included.

Here, the seating panel portion 21, as shown in FIGS. 4 and 5, is bent and extended from the top seating panel 22 seated on the upper end of the handrail 1 and the top seating panel 22, and the handrail (1) a handrail close-contact panel 23A in close contact with the outer wall and a handrail spaced panel 23B bent and extended from the upper mounting panel 22 and spaced apart from the inner wall of the handrail 1 by a predetermined distance in parallel can include

The handrail close panel 23A is formed by bending the outer end of the handrail 1 of the top seating panel 22 downward at right angles, and the handrail spacing panel 23B is the handrail 1 of the top seating panel 22. ) It may be formed by bending the end of the inward direction perpendicularly to the bottom.

The handrail contact panel 23A of the seating panel portion 21 is in close contact with the outer wall of the handrail 1 to prevent shaking (or play) of the antenna device A due to external forces such as wind pressure transmitted to the antenna device A. It can have an area that can withstand it.

Therefore, the handrail contact panel 23A may be formed larger than the area of the handrail spaced panel 23B if it has a sufficient area when the vibration reducing unit 27 described later is installed.

The seating panel portion 21 configured as described above is seated so as to surround the upper end of the handrail 1 corresponding to a portion where the horizontal support beam 15 is orthogonal to the handrail 1, which will be described later. It is temporarily assembled and fixed by the vibration reduction unit 27, and the front end of the horizontal support beam 15 can be fixed to the upper surface.

To this end, as shown in FIGS. 4 and 5, the seating panel portion 21 is formed integrally with the top seating panel 22 and is seated so as to surround a portion of the front end of the horizontal support beam 15. It may further include a horizontal beam mounting rib (22A) of.

The pair of horizontal beam mounting ribs 22A extend perpendicularly upward with respect to the upper surface of the upper mounting panel 22 and may be arranged parallel to each other to correspond to the length of the horizontal support beam 15 in the width direction. .

The front end of the horizontal support beam 15 is seated between the pair of horizontal beam mounting ribs 22A, and although not shown, the front end of the horizontal support beam 15 is mounted on the horizontal beam mounting rib through a welding coupling method and a bolting coupling method. It can be firmly fixed with respect to (22A).

On the other hand, as shown in FIGS. 4 and 5, the vibration reducing unit 27 includes a clamping bolt 28 fastened horizontally through the handrail spacing panel 23B and a clamping nut assembled to the clamping bolt 28. 29 and the clamping bolt 28 provided at the front end, and may include an elastic part 30 elastically supported on the inner wall of the corner side of the handrail 1.

Here, the elastic part 30 is screwed into the spring fastening hole (reference numeral not shown) provided at the front end of the clamping bolt 28, and gradually from the center of the front end of the clamping bolt 28 toward the handrail 1 side. It may be provided with a dish-shaped spring of increasing diameter.

As shown in FIGS. 4 and 5, the vibration reducing unit 27 configured as described above has a male thread, not shown, for fastening the clamping nut 29 to the outer circumferential surface of the clamping bolt 28. After being through-fastened to the spaced panel 23B, the clamping nut 29 is fastened to determine the clamping force by screwing, and the elastic part 30 is also attached to the front end of the clamping bolt 28 on the side of the spring fastening hole having a female thread. It can be fastened by screw coupling method.

The vibration reducing unit 27 serves to tightly clamp the handrail contact panel 23A and the elastic part 30 to the inner and outer walls of the handrail 1 when the clamping nut 29 is tightened. carry out

Here, as the vibration reducing unit 27 is provided so that the elastic unit 30 is elastically supported on the inner wall of the handrail 1, for example, external factors such as movement or shaking of the antenna device A due to wind It can also play a role of reducing vibration at the same time. That is, when the antenna device is installed on the railing 1 forming the corner of the roof top, the antenna device (A) is subjected to frequent wind pressure due to strong wind, and the vibration reduction unit 27, the antenna device (A) External vibration is reduced by being configured so that the elastic part 30 is supported on the handrail 1 elastically against flow or shaking, including all of the components of the floor support part 10 and the mounting parts 40 and 50 including And, it has the advantage of being able to block noise generation due to vibration in advance.

6 is a partially exploded perspective view and partially enlarged view showing a steering unit of the antenna device, and FIGS. 7 and 8 are partially exploded perspective views, partially enlarged views, and cut-away perspective views showing a tilting unit of the antenna device.

As referenced in FIGS. 6 to 8 , the antenna device A may be mounted on the upper end of the vertical support beam 13 via the mounting parts 40 and 50 to enable tilt rotation and steering rotation.

Here, the mounting parts 40 and 50 tilt and rotate the upper end of the antenna device A coupled to the upper end of the vertical support beam 13 in the forward and backward directions with respect to the lower end, as referred to in FIGS. 6 to 8 . It may include a tilting means 40 and a steering means 50 for steering and rotating both left and right ends of the antenna device A coupled to the upper end of the vertical support beam 13 in the left and right directions.

The steering means 50 mediates the coupling of the antenna device A to the vertical support beam 13, and when the antenna device A is tilted and rotated in the forward and backward directions by the tilting means 40, steering tilted in conjunction with Mounting panel 51, a pair of left and right steering guide slots 52 formed through a predetermined steering rotation trajectory in the vertical direction of the steering mounting panel 51, and a lower portion of the pair of left and right steering guide slots 52 It may include a pair of left and right steering guide bolts 53 that pass through and are fastened to the lower surface of the antenna device A.

Here, the steering mounting panel 51 is a vertical support beam (not shown) via a tilting axis (not shown) passing through the tilting panel 41 and the tilting guide panel 43 in the left and right directions among the tilting means 40 described later. 13) can be coupled to the upper end.

On the other hand, as referenced to FIGS. 6 to 8 , the tilting means 40 is on the lower surface of the steering mounting panel 51 provided to mediate the coupling of the antenna device A to the vertical support beam 13 The tilting panel 41 is integrally formed, but a part of the tilting panel 41 is hinged to form a tilting axis inside the vertical support beam 13, and the left and right sides of the tilting panel 41 are parallel to the tilting panel 41. A pair of tilting guide panels 43 integrally formed on the lower surface of the steering mounting panel 51 to be connected to the lower end of the tilting panel 41, and tilting the tilting panel 41 forward and backward at a predetermined angle A tilting adjustment bolt 45 may be included.

Here, both ends of the tilting rotation axis (not shown) may be hingedly fixed to the tilting axis holes 49 formed on both left and right surfaces of the upper end of the vertical support beam 13 .

In addition, worm wheel gear teeth 42 are formed on the outer circumferential surface of the lower end of the tilting panel 41, and a portion of the outer circumferential surface of the tilting adjustment bolt 45 is engaged with the worm wheel gear teeth 42 of the tilting panel 41. Worm gear teeth 46 ) can be formed.

The tilting adjustment bolt 45 may be horizontally coupled to the inside of the upper end of the vertical support beam 13 in the front and rear directions.

In addition, the tilting adjustment bolt 45 is provided with a tilting adjustment unit (reference numeral not indicated) exposed to the outside through the vertical support beam 13 corresponding to the inner direction of the handrail, and the tilting adjustment bolt 45 through the tilting adjustment unit ), the tilting angle of the antenna device A may be adjusted according to the amount of rotation.

More specifically, the tilting adjustment bolt 45 is fixed so that the front end portion is rotationally supported by the hinge installation portion 47A provided at the front end portion of the vertical support beam 13, and the tilting adjustment portion at the rear end of the vertical support beam 13 ) can be installed to be exposed through the rear end of the

Here, the operator sets the rotation amount of the tilting adjustment bolt 45 using a predetermined manipulation tool capable of rotating the head of the bolt (ie, the tilting adjustment unit), thereby adjusting the tilt rotation angle of the antenna device A. that can be coordinated.

On the other hand, the tilting means 40 is integrally formed on the upper surface of the vertical support beam 13, the tilting slot 44A through which the lower end of the tilting panel 41 passes, and a pair of tilting guide panels 43 It may further include a tilting mounting panel 44 having a pair of tilting guide slots 44B through which the lower end passes.

Here, the tilting means 40 and the steering means 50 are disposed at the upper end of the vertical support beam 13, which is relatively accessible to the installation worker, so that the installation worker or the manager of the antenna device A can easily tilt the tilting means (40) and the steering means (50), it provides an advantage of being able to easily adjust the direction of the antenna device (A).

On the other hand, a control box (C) is further installed in the middle of the vertical support beam (13), and the optical cable (A-3) connecting the control box (C) and the antenna device (A) is a steering mounting panel (51). It can be installed to be hidden from the outside by a concealing cover (A-2) installed on the rear side of the antenna device (A) while penetrating the top and bottom.

Here, in the hidden cover (A-2), a plurality of heat sink fins (reference numerals not indicated) formed on the rear surface of the antenna device (A) for system heat dissipation are contacted by a worker or an unspecified person accessible to the roof top to cause an image. It serves to prevent wearing and at the same time, as described above, by preventing the optical cable (A-3) from being exposed to the outside, it can play a role in preventing damage to the appearance of the building including the antenna device (A).

The hidden cover A-2 may be formed with a plurality of air flow holes A-2h through which outside air flows into the inside to facilitate heat transfer with the outside air through a plurality of heat sink fins.

In addition, between the lower end of the hidden cover (A-2) and the rear surface of the antenna device (A) may be disposed spaced apart from a predetermined distance or provided with a through installation so that the optical cable (A-3) can pass through.

In this way, according to the installation device of the antenna device for the roof top corner according to an embodiment of the present invention, the height of the floor support part 10 is easily adjusted without changing the shape of the roof top and the railing on the corner side of the roof top (1) It is possible to install through simple clamping and bolting for the bar, it is possible to improve installation convenience and create an effect capable of meeting various regulations of the country of installation.

In addition, according to an embodiment of the antenna device installation device for the rooftop corner according to the present invention, a plurality of antenna devices (A, A1 ~ A3) can be installed, and the weight of each component can be separated and combined so that a single installer can carry it, thereby providing an advantage of improving installation convenience.

The above has been described in detail with reference to the accompanying drawings, the installation device of the antenna device for the rooftop corner according to an embodiment of the present invention. However, it should be taken for granted that the embodiments of the present invention are not necessarily limited by the above-described embodiment, and various modifications and implementation within the equivalent range are possible by those skilled in the art to which the present invention belongs. will be. Therefore, it will be said that the true scope of the present invention is determined by the claims described later.

The present invention, while meeting the installation height regulations of the country in which it is installed, can easily install the antenna device on the corner railing of the roof top without changing the exterior of the building, and is easy to install on the upper end of the holding pole, as well as hiding the cable Provided is an installation device for an antenna device for a rooftop corner that can be installed to prevent deterioration in appearance.

Claims (20)

1. A floor support part installed on a corner-side handrail of the roof top, disposed on the inner bottom surface of the roof top handrail, and extending upward, a part of which is parallel to the handrail;

   a pair of handrail support portions extending horizontally from an upper portion of the floor support portion toward the handrail, respectively; and

   a mounting portion coupled to an upper portion of the floor support portion and having an antenna device mounted thereon; Including, the installation device of the antenna device for the rooftop corner.
2. The method of claim 1,

   The floor support part,

   a plurality of weight blocks;

   A floor support panel installed on the bottom surface of the roof top so that the plurality of weight blocks are mounted, an frame frame forming an edge end of the floor support panel, and a diagonal connection frame arranged to cross each other to connect diagonal lines of the frame frame. , Lower support portion including; and

   At the intersection of the diagonally connected frames, a vertical support beam and a lower end extending in a vertical direction parallel to the handrail to a predetermined height are connected to each middle portion of the frame frame, and an upper end obliquely extends from the lower end to the middle of the vertical support beam. An upper support portion including at least two or more inclined support beams connected to the portion; Including, the installation device of the antenna device for the rooftop corner.
3. The method of claim 2,

   The upper support portion and the lower support portion are mutually coupled to each other by one of a welding coupling method and a bolting coupling method, installation device of an antenna device for a rooftop corner.
4. The method of claim 2,

   The plurality of weight blocks are provided with a metal material of 30 kg or less, respectively, and can be individually seated on the upper surface of the floor support panel between the frame frame and the diagonal connection frame.
5. The method of claim 2,

   Any one of the vertical support beam and the at least two or more inclined support beams is provided so that the internal space communicates with each other,

   An installation device for an antenna device for a rooftop corner, wherein a wire installation hole into which an external wire is inserted is formed at the lower end of any one of the at least two or more inclined support beams.
6. The method of claim 2,

   The pair of handrail support parts, each horizontally extending toward the upper end of the handrail adjacent to each other in the middle of the vertical support beam, at least two horizontal support beams extending from the upper end of the inclined support beam; Including, the installation device of the antenna device for the rooftop corner.
7. The method of claim 6,

   The pair of handrail support parts,

   a seating panel unit coupled to surround the upper end of the handrail; and

   a vibration reduction unit supported on an inner wall of the handrail; Further comprising, the installation device of the antenna device for the rooftop corner.
8. The method of claim 7,

   Wherein the at least two or more horizontal support beams are seated and coupled to the seating panel portion so that the front end portion supports the seating panel portion in the direction of gravity.
9. The method of claim 7,

   The seating panel part,

   a top seating panel seated on an upper end of the handrail;

   a handrail adhering panel that is bent and extended from the upper seating panel and adheres to the outer wall of the handrail; and

   a handrail spaced panel that is bent and extended from the upper seating panel and disposed in parallel with a predetermined distance from the inner wall of the handrail; Including, the installation device of the antenna device for the rooftop corner.
10. The method of claim 9,

    The seating panel part,

    a horizontal beam mounting rib integrally formed with the upper mounting panel and seated so as to surround a portion of the front end of the horizontal support beam; Further comprising, the installation device of the antenna device for the rooftop corner.
11. The method of claim 7,

    The vibration reduction unit,

    a clamping bolt fastened horizontally through a handrail spaced panel spaced apart in parallel with respect to the inner wall of the handrail;

    a clamping nut assembled to the clamping bolt; and

    an elastic part provided at the front end of the clamping bolt and elastically supported on the inner wall of the handrail; Including, the installation device of the antenna device for the rooftop corner.
12. The method of claim 11,

    The elastic part,

    It is screwed into the spring fastening hole provided at the front end of the clamping bolt, and is provided with a dish-shaped spring whose diameter gradually increases from the center of the front end of the clamping bolt toward the handrail. Installation device of antenna device for rooftop corner.
13. The method of claim 2,

    The mounting part,

    tilting means for tilting and rotating the upper end of the antenna device coupled to the upper end of the vertical support beam in the forward and backward directions around the lower end; and

    Steering means for steering and rotating both left and right ends of the antenna device coupled to the upper end of the vertical support beam in left and right directions; Including, the installation device of the antenna device for the rooftop corner.
14. The method of claim 13,

    The steering means,

    a steering mounting panel that mediates coupling of the antenna device to the vertical support beam and is tilted in conjunction with when the antenna device tilts and rotates in the forward and backward directions by the tilting unit;

    a pair of left and right steering guide slots formed through a predetermined steering rotation trajectory in the vertical direction of the steering mounting panel; and

    a pair of left and right steering guide bolts passing through the lower part of the pair of left and right steering guide slots and fastened to a lower surface of the antenna device; Including, the installation device of the antenna device for the rooftop corner.
15. The method of claim 14,

    The steering mounting panel is coupled to the upper end of the vertical support beam via the tilting means, the installation device of the antenna device for the rooftop corner.
16. The method of claim 13,

    The tilting means,

    A tilting panel integrally formed on the lower surface of the steering mounting panel provided to mediate the coupling of the antenna device to the vertical support beam, a part of which is hinged to form a tilting axis inside the vertical support beam;

    a pair of tilting guide panels integrally formed on a lower surface of the steering mounting panel to be parallel to the tilting panel on both left and right sides of the tilting panel; and

    a tilting adjustment bolt connected to a lower end of the tilting panel and tilting the tilting panel at a predetermined angle in a forward and backward direction; Including, the installation device of the antenna device for the rooftop corner.
17. The method of claim 16

    Worm wheel gear teeth are formed on the outer circumferential surface of the lower end of the tilting panel, and worm gear teeth meshed with the worm wheel gear teeth are formed on a part of the outer circumferential surface of the tilting adjustment bolt.

    The tilting adjustment bolt is horizontally coupled to the inside of the upper end of the vertical support beam in the front and rear directions, the installation device of the antenna device for the rooftop corner.
18. The method of claim 16

    The tilting adjustment bolt is provided with a tilting adjustment unit exposed to the outside through the vertical support beam corresponding to the inward direction of the handrail,

    An installation device for an antenna device for a rooftop corner, in which a tilting angle of the antenna device is adjusted according to a rotation amount of the tilting adjustment bolt through the tilting adjusting unit.
19. The method of claim 16

    The tilting means,

    A tilting mounting panel integrally formed on the upper surface of the vertical support beam and having a tilting slot through which the lower end of the tilting panel passes and a pair of tilting guide slots through which the lower end of the pair of tilting guide panels passes; Further comprising, the installation device of the antenna device for the rooftop corner.
20. The method of claim 14,

    A control box is further installed in the middle of the vertical support beam,

    The optical cable connecting the control box and the antenna device passes through the steering mounting panel vertically, but is installed to be hidden from the outside by a concealing cover installed on the rear surface of the antenna device. Installation device for antenna device for a rooftop corner.

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